SU938158A1 - Stroboscopic meter of network dispersion parameters in time area - Google Patents

Description

The invention relates to electrical engineering and can be used to measure the frequency parameters of the scattering of radio circuits.

The closest in technical essence is a stroboscopic meter circuits scattering parameters in the time domain comprising a sounding pulse generator, a control input coupled to the second output electron computation ^- Call duration machines and synchronizing output - to an input of synchronization of the first stroboscopic converter, whose output is connected to the first Valid meter, and analog signal output - to the first input of the two-channel analog-to-digital converter whose output svya- ₂₀ coupled to the input e electronic computer, the first output connected to the input of the digital-analog converter, the output of which is connected (1) (1>

(¾) to the input of the display unit, and two matched loads [1]. .

The known device measures the frequency parameters of scattering of objects using the fast Fourier transform of pulsed signals transmitted through the object and reflected from it.

The scattering parameters of the object are determined by the formulas:

F (~ b)) "c <

Wf Fyu _Vl (-t) ^, j

938J where F is the operation of the fast Fourier transform;

Unit) - probe pulse signal υθ / t), - voltage pulses reflected from the input and output of the object under study;

^U np-i · ^Ira. voltage pulses, pro | coming from the entrance to the exit and from the exit to the entrance of the studied object.

The disadvantages of this device are the long measurement time, due to the need for manual switching of the blocks, and the large measurement error due to the heterogeneity of the microwave connectors and the nonlinearity of the paths of vertical and horizontal deviations.

The purpose of the invention is the reduction of time and measurement error.

This goal is achieved by the fact that the stroboscopic meter of the parameters of the scattering of circuits in the time domain, containing a probe pulse generator, the control input of which is connected to the second output of the electronic computer, and the synchronization output is connected to the synchronization input of the first stroboscopic converter, the output of which is connected to the first input of the meter , and the output of the analog signal - to the first input of a two-channel analog-to-digital converter, the output of which is connected to the input of the electronic computer the bus, the first output connected to the input of the digital-analog converter, the output of which is connected to the input of the display unit, and two matched loads, is equipped with three coaxial microwave switches and a second stroboscopic converter, the synchronization input of which is connected to the synchronization output of the probe signal generator, the analog signal output with the second input of the analog-to-digital converter, the output with the second input of the meter, and the input with the input of the third switch, the first

4 whose output is connected to the second coordinated load, and the output is connected to the second output of the second switch. Whose input is connected; to the output of the probe pulse generator, and the first output to the second output of the first switch, the first output of which is connected to the first matched load, and the input) to the input of the first stroboscopic converter, as well as the fact that it is equipped with fourth, fifth and sixth coaxial microwave switches and a calibration signal generator, the control input of which is connected to the third output of the electronic computer, and the output is connected to the input of the fifth switch, the first output of which is connected to the first the output of the fourth switch, the second output to the first output of the switch, the input of which is connected to the output of the second stroboscopic converter, and the second output to the second input of the meter, the first input of which is connected to the second output of the fourth switch, the input connected to the output of the first stroboscopic j converter.

Figure 1 and 2 shows the structural electrical circuits of the device.

_s The device (Fig. 1) consists of the first, second and third coaxial microwave (microwave) switches 1,2 and 3, the first and second matched loads 4 and 5, the probe signal generator 6, the first and second stroboscopic converters 7 and 8, digital-to-analog converter 9, electronic computing machine (computer) 10 ^ two _s channel analog-to-digital converter (ADC) 11 and the display unit 12.

The device (figure 2) contains D ° * in addition to the fourth, fifth and sixth coaxial microwave switches ³ 13, 14 and 15 and a calibration signal generator 16. '

The device (figure 1) works as follows.

When measuring parameters ^S 4i ^{and 5 S} according to commands from the computer 10, switch 1 is set to position B, switches 2 and 3 ~ to position A. This ensures

938158 6 singing the probe signal to the input of the transducer 7 and registering the signal reflected from the object using the transducer 7. Using the converter δ, a signal 5 transmitted through the object is recorded. The computer starts the generator 6 of the probe pulses, which runs the stroboscopic transducers 7 and 8.

At the analog outputs of the stroboscopic converters 7 and 8, signals are generated that are equal to the signals at their high-frequency inputs at the time of start-up. These signals are fed to the inputs of the ADC 11, which is also triggered ^{15 by the} computer 10.

According to the signal from the computer 10, the signal codes of the first and second channels of the ADC 11 are read into the computer memory. The process is repeated until arrays of signals Пш are generated in computer memory 20, ^and 04> - The calculations are carried out using formulas (1) and (2) with the replacement of 1) ^ by And ^ _4. After that, through a digital-to-analog converter 25 9 The computer 10 displays information on the screen of the display unit 12.

Measurement of parameters S and is carried out in a similar way. While switches & ustanavliva- LP are position 1 - position A, 2 - B in position 3 'in position B. record signals, ^ 02 »U IRPP formulas (3) and (4) ₃₅ Manu- dyatsya calculations on U _n2 _ ^{and the} result is displayed on the screen of the display unit 12.

The device (figure 2) works as follows. di

The recording of signals in the memory of the computer 10 is made in this device in the same way as in the device shown in Fig.1. After recording, the stroboscopic transducers 7 and 8 are calibrated. The switches 1,3 »13 and 15 are set to position A upon command from the computer 10. The calibration signal in the form of a meander with a stable period and a fixed set of precision voltage levels is alternately fed to the inputs of the transducers 7 and 8 .

In the memory of the computer software tables are recorded, the measured values of the meander periods in ⁵⁵ for the duration of the scan used, the amplitude of the fixed levels.

Based on these data, the parameters of a cubic polynomial characterizing the non-linearity of the sweep of the stroboscopic transducer and the vertical deflection path, i.e. the functions are determined, (b) - o, -t + a \ a for each channel, which make it possible to eliminate the nonlinearity of the paths of horizontal and vertical deviation.

The scattering parameters of the circuit are determined by the formulas:

'_ ₍₅₎ _ HWozEWlB, _f7 , ^S 22 (wr where is the function characterizing the nonlinearity of the vertical path of the converter;

Ψγ - A function that characterizes the nonlinearity of the horizontal path of the converter. The device allows you to automate the measurement process, reduce non-linear distortions in the paths of vertical and horizontal deviations, take into account systematic errors and eliminate random errors due to the heterogeneity of the microwave connectors. As a result of this, the measurement time is reduced, and the measurement accuracy is increased.

Claims (2)

The invention relates to electrical measuring technique and can be used in measuring the frequency parameters of a scattered radio circuit. The closest in technical essence is a stroboscopic measuring instrument for scattering circuits in the time domain, which contains a probe pulse generator, the control input of which is connected to the second output of the electronic computer, and the synchronization output is connected to the synchronization input of the first stroboscopic converter, which output connected to the first input of the meter, and the output of the analog signal to the first input of a two-channel analog-to-digital converter, the output of which is connected to the input electrons computing machine, a first output connected to the input of the digital to analog converter whose output is connected to Ch B from n ro us de entry display unit, and two soasovannye load fl. The known device measures the frequency parameters of the scattering of objects using the fast Fourier transform of pulsed signals that have passed the object and are reflected from it. The parameters of the object scattering are determined by the formulas: -), 14) FjUna). 4HW) s. Tllvuyy FlUogC-i) 4lCW) FVUvit-t). where F is the fast Fourier transform operation; Untt) - probe pulse signal; - voltage pulses, reflected from the input and output of the object under study; mp-1 (ir1, (t) voltage pulses transmitted from the input to the output and from the output to the input of the object under study. The disadvantages of this device are the long measurement time, due to the need) of manual switching of the blocks, and the large measurement uncertainty, due to the heterogeneity of the microwave connectors and the nonlinearity of the paths of the vertical and horizontal deviations. The purpose of the invention is to reduce the time and error of measurement. This goal is achieved by the fact that a stroboscopic measuring instrument for scattering circuits in the time domain, containing a probe pulse generator, the control input of which is connected to the second output of the electronic computing bus, and the synchronization output to the synchronization input of the first stroboscopic converter, the output of which is connected to the first input of the meter, and the output of the analog signal to the first input of the two channel analog-digital converter, the output of which is connected to the input of the electronic-computing the bus, the first output connected to the input of a digital-to-analog converter, the output of which is connected to the input of the display unit, and two coaxial loads, is equipped with three coaxial microwave switches and a second stroboscopic converter, the synchronization input of which is connected to the output of the generator synchronizing probe signals, the output of the analog signal with the second input of the analog-to-digital converter, the output with the second input of the meter, and the input with the input of the third switch, the first 9 4 output of which The second is connected to the second matched load, and the w / o output is connected to the second output of the second switch, whose input is connected to the output of the probe pulse generator, and the first output to the second output of the first switch, the first output of which is connected to the first matched load, and the input the input of the first stroboscopic converter, as well as the fact that it is equipped with the fourth, fifth and sixth coaxial microwave switches and a calibration signal generator, the control input of which is connected to the third the output of the electronic computer, and the output with the input of the fifth switch, the first output of which is connected to the first output of the fourth switch, the second output to the first output switch, whose input is connected to the output of the second stroboscopic converter, and the second output with the second input meter, the first input of which is connected to the second output of the fourth switch, the input connected to the output of the first stroboscopic converter. Figure 1 and 2 shows the structural electrical circuits of the device. The device (figure 1) consists of first, second and third coaxial microwave (UHF) switches 1,2 and 3i of the first and second matched loads A and 5, generator 6 of probing signals, first and second stroboscopic converters 7 and 8, digital-analog converter 9 , an electronic computer (computer) lOj two-channel analog-digital converter (ADC) 11 and the block 12 of the display. The device (figure 2) contains up to the fourth, fifth and sixth coaxial microwave switches 13, 1 and 15 and the generator 16 of the calibration signal. The device (Fig. 1 operates as follows. When measuring parameters 5 and S according to commands from computer 10, switch 1 is set to position B, switches 2 and 3 are set to position A. This ensures that the probe signal arrives at the input of converter 7 and is recorded with converter 7 of the signal reflected from the object. Using the converter b, the signal transmitted through the object is recorded. The computer starts the generator of 6 probe pulses, which starts the stroboscopic converters 7 and 8. On the analogue The outputs of the stroboscopic transducers 7 and 8 produce signals equal to the signals at their high-frequency inputs at the trigger times.These signals go to the inputs of the ADC 11, which also starts the computer 10. The signal from the computer 10 codes the signal of the first and second channels of the ADC 1 1 is read computer memory. The process is repeated until the arrays of signals J are formed in the computer memory, and,. Further, calculations are made using formulas (1) and (2) with replacement of Uj by i. this through digital-to-analog converter 9 computer 10 displays information on the screen of the display unit 12. Measurements of the parameters S 2 and S are carried out in a similar way. In this case, the switches are set to S positions: 1 - to position A, 2 - to position B, 3 to position B. Signals Uy are recorded. Wooi. .. By the formulas (3) and (h), the calculations of U on Uy are performed, and the result is displayed on the screen of the display unit 12. The device (figure 2) works as follows. The signals are stored in the computer memory 10 in this device in the same way as in the device shown in Fig. 1. After recording, calibration of the stroboscopic transducers 7 and 8 is performed. Switches 1.3 13 and 15 are set to position A by a command from computer 10. Transducers 7 and 8 are alternately fed a calibration signal in the form of a square wave with a stable period and a fixed set of precision voltage levels. . Tables, measured meander period values for the duration of the used sweep, amplitudes of the fixed levels are recorded in software memory by software. 9 6 On the basis of these data, the dimensions of a cubic polynomial characterizing the nonlinearity of the sweep of a throboscopic transducer of the vertical deflection path, i., Are determined by the method of Gression analysis. the functions, 4Ct) -c, are determined. , nv) - b ,, l of each channel, allowing the nonlinearity of the horizontal and vertical deviation paths to be stranded. The parameters of the scattering circuit are determined by the formulas:, C% Ct) l (5) 5i4vc /), wa) ii (p. 1IRp1 gC-b) 1b (b) aitw) - f vViCUn.),, IUoa.) ll, aaCw) - R ChGIIGICHa) F a UHpaI fret) 3 p. ncvx /) - F H-aLUM-ilMt) where is the function characterizing the nonlinearity of the transducer's optical path; PV A function that characterizes the nonlinearity of the horizontal path of the converter. The device allows you to automate the measurement process, reduce nonlinear distortion in the paths of the vertical and horizontal deviations, take into account systematic errors and eliminate random errors due to the heterogeneity of the microwave connectors. As a result, the measurement time is shortened, and the measurement accuracy is improved. Claims 1. Stroboscopic meter for scattering of circuits in time. variable region, containing a generator of probe pulses, the control input of which is connected to the second 7 the output of the electronic computer and the synchronization output to the synchronization input of the first stroboscopic converter, the output of which is connected to the first input of the meter, and the output of the analog signal to the first input of a two-channel analog digital converter, the output of which is connected to the input of the electronic computer, the first output connected to the input of a digital-to-analog converter, the output of which is connected to the input of the display unit, and two matched loads, characterized in that, in order to reduce time and measurement error, it is equipped with three coaxial ultra-high frequency switches and a second stroboscopic converter, the synchronization input of which is connected to the synchronization output of the probe signal generator, the analog signal output — with the second input of the analog-digital converter, the output — with the second meter input, and input - to the input of the third switch, the first output of which is connected to the second matched load, and the second output - to the second output of the second switch, which is connected to the output of the probe pulse generator, and the first one to the second output of the first switch, the first output of which is associated with the first matched n-load, and the input to the input of the first strooscopic converter, 2. The meter according to claim 1, of which is equipped with a fourth, fifth and sixth coaxial microwave switches and a generator of a calibration signal, the control input of which is connected to the third output of the electronic computer, and the output with the input of the fifth switch, the first output of which is connected to the first output of the fourth switch, the second output - to the first output of the sixth switch, whose input is connected to the output of the second stroboscopic converter, and the second output - with the second input m meter, the first input of which is connected to the second output of the fourth switch, the input connected to the output of the first stroboscopic converter. Sources of information taken into account with the expert 1. Andrews J. Automatic determination of the parameters of electrical circuits through measurements in the time domain. TIIER, t.66, No. A, 197B, p. 5b (prototype). fi